DE102017128068A1 - Electronic device - Google Patents

Abstract

The object of the present invention is to provide an electronic device which can utilize the vibrations of a vibration generating device. The present object is achieved by an electronic device 1001 comprising a housing 1010, a contact component 1020 fixed to the housing 1010 and a vibration generating device 1. The vibration generating device 1 is fixed to the contact component 1020 or the housing 1010. Between the housing 1010 opposite side of the vibration generating device 1 and the vibration generating device 1 opposite side of the housing 1010, a gap is provided.

Description

FIELD OF THE INVENTION

The present invention relates to an electronic device, in particular an electronic device having a vibration generating device.

TECHNICAL BACKGROUND

There are electronic devices that are equipped with a vibration generating device.

In JP 2015-70729 A For example, there is disclosed a structure in which a vibration actuator is attached to a touch panel of a data terminal processing apparatus via a vibration transmitting component that lowers the frequency of the vibrations and transmits the vibrations to the touch panel.

DESCRIPTION

Object of the invention:

However, in such an electronic device, it is necessary to attach a vibration generating device to the electronic device so that the vibration force generated by the vibration generating device can be transmitted to a component of the electronic device.

The present invention has been made to solve such a problem and is intended to provide an electronic device that can utilize the vibrations of a vibration generating device.

Means for solving the task:

To achieve this object, the electronic device according to one aspect of the present invention comprises a housing, a contact component fixed to the housing, and a vibration generating device, wherein the vibration generating device is fixed to either the contact component or the housing between the housing opposite surface of the vibration generating device and the vibration generating device opposite surface of the housing, a gap is provided.

Preferably, the vibration generating device is coupled to or fixed to the contact component directly or via another component, the vibration generating device comprising a base and a plate movable relative to the base, the plate extending in relation to the base - And adjustment can come into contact with the contact component or be spaced from this.

Preferably, the vibration generating device comprises a first elastic component for supporting the plate relative to the base, wherein the first elastic component for supporting the plate is deformed upon contact with the contact component.

Preferably, the vibration generating device comprises a first resilient component for supporting the plate relative to the base, the first resilient component for supporting the plate upon contact with the contact component in translation relative to the base shifting the plate towards the contact component.

Preferably, a second elastic component is provided between the plate and the contact component.

More preferably, the contact component is coupled to the housing via a third elastic component.

More preferably, a weight is provided on the plate.

More preferably, the vibration generating device is coupled to the outer periphery of the contact component.

According to the present invention, an electronic device that can use the vibrations of a vibration generating device can be provided.

list of figures

• 1 Fig. 15 is a perspective view showing an electronic device according to a first embodiment of the present invention.
• 2 is a perspective view of the vibration generating device.
• 3 is a perspective view of the internal structure of the vibration generating device.
• 4 is an exploded perspective view of the vibration generating device.
• 5 is a plan view of the vibration generating device.
• 6 is a cross section along the line A1-A1 in 5 ,
• 7 is a cross section along the line A2-A2 in 5 ,
• 8th FIG. 15 is a perspective view showing an elastic component according to a first modification. FIG.
• 9 FIG. 15 is a perspective view showing an elastic component according to a second modification. FIG.
• 10 FIG. 15 is a perspective view showing an elastic component according to a third modification. FIG.
• 11 FIG. 15 is a perspective view showing an elastic component according to a fourth modification. FIG.
• 12 FIG. 15 is a perspective view showing an elastic component according to a fifth modification. FIG.
• 13 FIG. 15 is a perspective view showing an elastic component according to a sixth modification. FIG.
• 14 FIG. 14 is a view showing the attachment structure of the vibration generating device to the electronic device. FIG.
• 15 FIG. 12 is a view showing the vibration generating apparatus in a state where current flows through the coil. FIG.
• 16 Fig. 15 is a perspective view showing a first modification of the attachment structure of the vibration generating apparatus.
• 17 Fig. 12 is a cross section showing the first modification of the attachment structure of the vibration generating apparatus.
• 18 Fig. 10 is a plan view showing a second modification of the attachment structure of the vibration generating apparatus.
• 19 is a cross section along the line CC in 18 ,
• 20 FIG. 15 is a perspective view showing a modification of the electronic device. FIG.
• 21 is a plan view of the vibration generating device according to a second embodiment.
• 22 is a cross section along the line EE in 21 ,
• 23 Fig. 16 is a view showing a modification of the second embodiment.
• 24 FIG. 10 is a plan view of the vibration generating apparatus according to a third embodiment. FIG.
• 25 is a cross section along the line GG in 24 ,
• 26 is a cross section of the vibration generating apparatus according to a fourth embodiment.
• 27 is a cross section of the vibration generating device according to a fifth embodiment.
• 28 FIG. 15 is a perspective view showing the vibration generating apparatus according to a sixth embodiment. FIG.
• 29 FIG. 10 is an explanatory view of the structure of the vibration generating apparatus according to the sixth embodiment. FIG.
• 30 FIG. 15 is a perspective view showing the vibration generating apparatus according to a modification of the sixth embodiment. FIG.
• 31 FIG. 14 is an explanatory view of the structure of the vibration generating apparatus according to the modification of the sixth embodiment. FIG.

DETAILED DESCRIPTION OF EMBODIMENTS

In the following, an electronic apparatus including the vibration generating apparatus according to an embodiment of the present invention will be explained.

The coordinates, which are respectively shown in the following figures, serve to represent the position of the vibration generating device. It happens that the X-axis direction as a left-right direction (the X-axis viewed from the origin in the positive direction represents the right direction), the Y-axis direction as a front-back direction (where the Y -Axis viewed from the origin in the positive direction represents the back direction) and the Z-axis direction (the direction orthogonal to the XY plane) as the top-bottom direction (the Z-axis viewed from the origin in the positive direction the top Direction). Furthermore, it can happen that the direction orthogonal to the Z-axis is called horizontal. Incidentally, the terms left-right, back-to-back, up-down, horizontal, etc. are merely illustrative of the structure and operation, and have no relation whatsoever to the location, purpose and circumstances in which the oscillations produce Device and the electronic device are used.

First Embodiment

1 Fig. 15 is a perspective view showing an electronic device according to a first embodiment of the present invention.

As in 1 illustrated comprises an electronic device 1001 a housing 1010 , a contact component 1020 and a vibration generating device 1 , In the electronic device 1001 is it z. B. a smartphone.

The contact component 1020 is z. As a touchpad or touch screen. The contact component 1020 is on the case 1010 attached.

The vibration generating device 1 generates a vibratory force on the electronic device 1001 is transmitted. In the present embodiment, the vibration generating device 1 with the contact component 1020 coupled directly or via another component or fixed to this. Incidentally, there is no limitation that the vibration generating device 1 with the contact component 1020 coupled directly or via another component or fixed to this, but this can also be with the housing 1010 be coupled directly or via another component or fixed to this.

Structure of the vibration generating device 1 ]

2 is a perspective view of the vibration generating device 1 , 3 is a perspective view of the internal structure of the vibration generating device 1 , 4 is an exploded perspective view of the vibration generating device 1 , 5 is a plan view of the vibration generating device 1 , 6 is a cross section along the line A1-A1 in 5 , 7 is a cross section along the line A2-A2 in 5 ,

As in 2 shown is the vibration generating device 1 overall formed in a thin plate shape. The vibration generating device 1 has a flat shape. In the vibration generating device 1 it is a small format with z. External dimensions in the left-right direction or in the front-back direction of about several dozen millimeters and outer dimensions in the up-and-down direction of about several millimeters, respectively. The vibration generating device 1 has, roughly speaking, a disc shape, with the exception of a portion in which a hole 11 is provided, an outer diameter of z. B. 20 millimeters and a thickness of about 3 millimeters.

As in 3 shown has the vibration generating device 1 a base 10, a plate 30 , a coil 40 and an elastic component 51 on.

The base 10 is formed of a magnetic body. The base 10 exists z. B. of metal. The base 10 exists z. B. iron. The base 10 is z. B. from a steel sheet by molding by means of z. B. a press formed. Incidentally, the base 10 also by z. For example, a cutting shaping can be formed.

As in 4 shown, indicates the base 10 a flange part 15 and a sunken part 14 on, below the flange part 15 sunk. The sunken part 14 has z. B. seen in the plane a round shape. In other words, the base points 10 an upwardly opened, thin, tubular portion (cylindrical portion with a bottom) on. The tubular portion has z. B. a columnar shape. The upper end of the tubular portion goes into the flange-shaped outwardly opened flange portion 15 above. In the present embodiment, the flange part 15 slightly widened in the left-right direction compared to the other sections, wherein a hole or holes 11 is / are formed in the widened section. As in 5 illustrated, the holes 11 are arranged on both sides right and left of the recessed portion 14 and z. B. when attaching the vibration generating device 1 on the electronic device 1001 be used.

As in 6 shown, the recessed part 14 a bottom part 14a and a side wall part 14b on. As in 4 shown was from the sidewall part 14b a part removed in front. In other words, is a part of the side wall part 14b sunk like a recess.

At the recess in the side wall part 14b is one of the bottom part 14a provided forwardly extending terminal plate 19. The terminal plate 19 is a projecting part coming from the side wall part 14b sticking out to the outside. On the connection plate 19 ports 19 a, 19 b are provided for the power supply to a coil 40. The terminals 19a, 19b are z. B. formed of flexible plates and adhered to the terminal plate 19. Incidentally, without the terminal plate 19 is provided, a part of the side wall portion 14b and the bottom part 14a be cut out so that a path for the power supply through the cut-out section is formed by the path for the power supply below or to the side of the base 10 to the coil 40 is provided.

In the present embodiment, at the top of the bottom part 14a a recess 17 and a groove portion 18 is formed. The depth from the top of the bottom part 14 a to the recess 17 and the groove part 18 becomes smaller than the depth in the top-bottom direction of the recessed part 14 (Distance from the top of the flange part 15 up to the top of the bottom part 14a ). The indentation 17 is substantially in the middle of the recessed part 14 educated. The indentation 17 is formed in a shape corresponding to the shape of a later-mentioned protruding part 20 fits. For example, the indentation 17 has a round shape seen in the plane. The groove part 18 is substantially from the center of the recessed part 14 formed to near the terminal plate 19. The groove part 18 extends, so that the front-back direction becomes the longitudinal direction, in the front-back direction from the recess 17 to the terminal plate 19.

As in 6 is shown at the base 10 a protruding part 20 intended. The above part 20 is in the middle of the base 10 arranged. The above part 20 has z. B. a cylindrical shape. In the present embodiment, the projecting part 20 a columnar form. The position of the upper end of the protruding part 20 in the top-bottom direction is substantially the same as the position of the top of the flange 15 , Incidentally, the position of the upper end of the protruding part 20 in the top-bottom direction but also higher or lower than the surface of the flange portion 35a.

In the present embodiment, the projecting part becomes 20 separated from the main part of z. B. a steel base formed 10 formed and attached to the main part of the base 10 attached. The above part 20 is based on the main body 10 fastened by being fitted in the indentation 17. The above part 20 is z. B. fastened by being glued or welded in the recess 17. The above part 20 is as well as the main part of the base 10 formed from a magnetic body. The above part 20 exists z. B. of metal. The above part 20 exists z. B. iron. The above part 20 acts as the core (iron core) of an electromagnet, which is the coil 40 used.

As in 4 shown is the coil 40 annular and has a flat shape. The sink 40 is a thin coil whose dimension in the winding axis direction is smaller than the dimension in the direction orthogonal to the winding axis direction. The sink 40 exists z. B. from a wound lead wire and is a total annular coil of a tablet form. Incidentally, the coil can 40 also be formed by winding a metal foil and sliced, or is piled into a sheet coil. Furthermore, the outer shape of the coil 40 seen in the plane also have a circular shape or a polygonal shape such as a rectangular shape.

The sink 40 is annularly wound so that it protrudes the part 20 surrounds. That is, the coil 40 is inside the submerged part 14 added. That is, the coil 40 is between the outer periphery of the protruding part 20 and the inner periphery of the side wall part 14b arranged. The sink 40 is formed so that the surface of the coil 40 not higher than the surface of the flange part 15 is positioned, and is at the base 10 attached. The coil previously wound into a toroidal plate shape 40 can also be at the base 10 be fastened by placing it in the recessed part 14 is fitted. It is also possible to use the coil 40 at the base 10 by forming a conductor wire the projecting part 20 surrounding directly on the base 10 is wound up.

Between the inner surface of the side wall part 14b , which is the outer circumference of the base 10 and an outer side surface 41 of the spool 40 a gap is provided. Further, between the outside surface of the protruding part 20 and an inner surface 42 of the coil 40 provided a gap. This becomes a contactless isolation state of the base 10 and the coil 40 ensured.

At the coil 40 is it z. B. is a lead wire of φ 0.15, which is wound with about 100 to 200 windings (eg., 150 windings). The execution of the coil 40 is not limited to this but may be the size and purpose of the vibration generating device 1 be suitably selected accordingly.

One end of the lead wire (coil end) 43a of the outside of the coil 40 passes the section where the side wall part 14b was cut out, and is from the interior of the recessed part 14 to the outside of the base 10 led out. Further, one end of the lead wire (coil end) 43b passes the inside of the coil 40 the bottom of the coil 40 and becomes the outside of the base from the portion where the side wall part 14b has been cut out 10 led out.

In the present embodiment, the coil end 43b passes through the groove part 18 and is from the inside of the coil 40 led out to the side of the connection plate 19. Thereby, the lead wire becomes the coil end 43b between the bottom of the coil 40 and the top of the bottom part 14a clamped so that it can be prevented that the lead wire is loaded or the insulation is lost. Incidentally, a cylindrical insulating component for passing the lead wire of the coil may also be used 40 be inserted to the insulation of the coil 40 and the base 10 sure.

The through the from the side wall part 14b cut out section on the outside of the base 10 led out winding ends 43a, 43b are each z. B. connected by means of soldering to the terminals 19 a, 19 b. The fact that a lead wire is connected from the outside to the terminals 19a, 19b, the coil can 40 Power is supplied through the lead wire. The terminals 19a, 19b are disposed on the terminal plate 19, so that the connection between the lead wire from the outside and the terminals 19a, 19b can be easily achieved.

The plate 30 has in the present embodiment a parallel to the horizontal, round plate shape. The plate 30 is formed of a magnetic body. The plate 30 exists z. B. of metal. The plate 30 exists z. B. iron. The plate 30 is z. B. from a steel sheet by molding by means of z. B. presses formed. Incidentally, the plate can 30 also by z. For example, a cutting shaping can be formed.

The plate 30 will be above the base 10 , the base 10 arranged opposite. As in 5 shown, the plate indicates 30 substantially the same dimension of the outer diameter as the dimension of the outer diameter of the periphery of the flange 15 except for the portion where the hole 11 is provided. The plate 30 is formed so as to have the flange portion except for the portion where the hole 11 is provided 15 covered. As in 7 shown, the bottom of the section is located near the outer periphery of the plate 30 the top of the flange 15 across from. In other words, the flange part 15 at a further outer location of the base 10 as the outer circumference of the coil 40 provided and lies the surface of the plate 30 across from.

As in 7 pictured is the plate 30 opposite the base 10 arranged at a small distance to form a magnetic circuit. Between the plate 30 and the base 10 is the elastic component 51 arranged. By placing the elastic component 51 will be between the plate 30 and the base 10 in a non-conductive state of the coil 40 provided a certain distance. That is, the plate 30 is located through the flange part 15 the base 10 by the proportion of the thickness of the elastic component 51 on the top at a higher position.

The elastic component 51 is deformable, wherein it is z. B. is a resin component having a restoring force. The elastic component 51 supports the plate 30 opposite the base 10 , The elastic component 51 is between the plate 30 and the base 10 intended. In the present embodiment, the elastic component is 51 arranged so that they are between the flange part 15 and the plate 30 is trapped. That is, the elastic component 51 is between the on the outside of the coil 40 positioned outer circumference of the base 10 and on the outside of the coil 40 positioned outer circumference of the plate 30 arranged.

The elastic component 51 is z. B. by means of an adhesive on the flange 15 glued on and fixed. Incidentally, the manner of providing the elastic component is not limited to sticking. Furthermore, the elastic component 51 also on the plate 30 However, it can also be fixed by placing each on the flange part 15 and at the plate 30 z. B. is glued. Furthermore, it is also possible that the elastic component 51 neither on the flange part 15 still at the plate 30 is fixed.

As elastic component 51 are four components (elastic components 51a, 51b, 51c and 51d, hereinafter also each as an elastic component 51 designated) provided. The four elastic components 51 are arranged side by side to several in the circumferential direction. The four elastic components are arranged in the circumferential direction with a certain distance. That is, as in 5 As shown, in the present embodiment, the elastic component 51a is left behind the protruding part 20 arranged. Right behind the protruding part 20 the elastic component 51b is arranged. Right before the previous part 20 is the elastic component 51 c arranged. Left in front of the protruding part 20 the elastic component 51d is arranged. If you pay attention to an elastic component 51 , are the circumferentially adjacent elastic components 51 roughly, at 90 degrees around the protruding part 20 arranged rotated positions.

The four elastic components 51 are at from the circumferentially adjacent elastic components 51 arranged distant positions. In other words, when considering the vibration generating device, there is 1 from the side, sections where between the plate 30 and the base 10 no elastic component 51 is present.

The elastic component 51 is deformable, these being after the recessed part 14 as space S between the plate 30 and the base 10 , Space S between two adjacent elastic components of the four elastic components 51 in the circumferential direction and as space S on the inside of the base 10 directed. Consequently, the space S takes part of the deformed elastic component 51 on, by providing this space S, the elastic component 51 after the sunken part 14 is directionally deformable.

Incidentally, the elastic component 51 not limited to four pieces, it can also be two or three pieces. Further, five or more may be provided. Furthermore, the elastic component 51 , as mentioned later, also be annular. The elastic component 51 is not on the gap between the flange part 15 and the plate 30 limited, and can also be between the top of the coil 40 and the plate 30 , or between the top of the protruding part 20 and the plate 30 be arranged.

In the present embodiment, the plate form 30 and the base 10 a magnetic circuit. The plate 30 is at the portion of the outer circumference with a certain distance to the flange 15 and in the middle section with a certain distance to the projecting part 20 at. Therefore, through the plate 30 and the base 10 that the protruding part 20 includes a magnetic circuit formed. The plate 30 and the base 10 are just about the proportion of the thickness of the elastic component 51 separated, so that a magnetic gap of this proportion is provided on the magnetic circuit. From the aspect of increasing the amplitude of the disk 30 (in terms of improving magnetic performance in the magnetic circuit), the smaller the gap, the better the magnetic gap.

The vibration generating device 1 is operated by a condition in which in the coil 40 an electric current flows and a state in which no electric current flows in the coil 40 is repeated. That is, by repeatedly magnetizing and demagnetizing the coil 40 and the base 10 formed electromagnets can by the vibration generating device 1 Vibrations are generated.

Flows into the coil 40 an electric current, becomes the base 10 excited. This will be the upper part of the base 10 and the flange part 15 to a magnetic pole piece and also the magnetic circuit forming plate 30 is magnetized. Between the upper part of the base 10 and the middle part of the plate 30 and between the flange portion 15 and the outer periphery of the plate 30 creates a relatively strong magnetic attraction, so the plate 30 opposite the base 10 is attracted. This shifts the plate 30 opposite the base 10 down, while the elastic component 51 is compressed, so the distance between the plate 30 and the base 10 gets smaller. If the elastic component 51 is guided from a compressed state in which in the coil 40 no electric current flows, there is a restoring force, so the plate 30 in from the base 10 wegführenden direction is shifted. Therefore, the maximum shift size of the disk is enough 30 to the position where the magnetic attraction force and the restoring force of the elastic component 51 are balanced. In the present embodiment, the upper part is the base 10 the above part 20 , Incidentally, the upper part is the base 10 not on the above part 20 but it can also be a point further down the side of the plate 30 as the bottom part 14a the base 10 is positioned.

Will the coil 40 from the state in which an electric current flows, led to the state in which in the coil 40 no electric current flows, the magnetization is canceled, so that the magnetic attraction is lost. In this case, it comes to a state in which the restoring force due to the displacement of the plate 30 to the base 10 compressed elastic component 51 on the plate 30 acts, so that the plate 30 opposite the base 10 moves up. This will clear the gap between the plate 30 and the base 10 greater.

As the state in which in the coil 40 an electric current flows, and the state in which in the coil 40 no electric current flows, to be repeated, is moving the plate 30 opposite the base 10 repeated in top-bottom direction. In other words, the plate shifts 30 opposite the base 10 in back and forth. As a result, by the vibration generating device 1 a vibration force can be generated. As a back and forth can z. B. the direction in which the plate 30 opposite the base 10 vibrates, or the thickness direction of the plate 30 and the base 10 to be named.

In the present embodiment, the outer circumference of the plate is located 30 the flange part 15 the base 10 across from. As a result, it comes on the outer side portion of the coil 40 not easy to leak the magnetic flux that passes the magnetic circuit (sinking of the magnetic resistance), so that a strong magnetic attraction arises. Therefore, the performance of the vibration generating device 1 be improved. Further, the plate 30, which becomes the vibration surface, on the size of the flange portion 15 be enlarged. As a result, powerful vibrations on z. B. the electronic device 1001 be transmitted.

The elastic component 51 is arranged so that these between the plate 30 and the base 10 is trapped. Hence the plate come 30 and the base 10 not even then in contact with each other when in the coil 40 an electric current flows. As a result, when operating the vibration generating device 1 the generation of noise due to contact between the plate 30 and the base 10 be prevented.

Considering the vibration generating device 1 from the side, there are sections where between the plate 30 and the flange part 15 no elastic component 51 is arranged. Will the elastic component 51 when the plate 30 opposite the base 10 shifts down, compresses, is the elastic component 51 therefore deformable not only in the radial direction, but also in the circumferential direction. Further, by changing the thickness, width, etc. of the elastic component 51 the vibration generating device 1 required restoring force (also referred to as elastic force) are obtained. Therefore, the shift amount of the disk 30 be increased against the strength of the magnetic attraction. The room where the coil 40 is provided, and the outside of the vibration generating device 1, are contacted by a portion in which between the plate 30 and the flange part 15 no elastic component is arranged. As a result, that of the coil 40 generated heat can be successfully radiated.

Incidentally, as the dashed two-dot line in 3 and 4 shows on top of the plate 30 the vibration generating device 1 a weight 30w can be arranged. In the event that on the plate 30 the weight is placed 30w, the plate shifts 30 together with the weight 30w, so that a stronger vibration force can be generated.

[Explanation of Modification of Elastic Component]

As the elastic component used in the vibration generating apparatus, there is no limitation to such as the above elastic component 51 but different versions can be used. That is, the execution of the elastic component may vary according to various factors, e.g. Example, the size of the vibration generating device, the size of the magnetic attraction force generated by a coil or the size of the required vibration force are suitably selected.

The material of the elastic component may also be appropriately selected according to such as the above factors. As an elastic component can, for. For example, a rubber, a synthetic resin, a gel-like component and a resin component such as a sponge having various bubbles may be used. Further, as a resilient component and a metallic component as in a spring, for. B. a leaf spring or a coil spring made of metal. These are examples, wherein as elastic component, various objects can be used, which are deformable and the plate 30 opposite the base 10 can support.

As the elastic component, a material containing a magnetic substance may also be used. Thereby, the elastic component can also be used as a component which forms the magnetic circuit together with the base and the plate. Thereby, in the magnetic circuit, the leakage of the magnetic flux is suppressed (sinking of the magnetic resistance), so that the performance of the vibration generating device 1 can be improved.

The elastic component may, for. B. also be carried out as follows.

8th FIG. 15 is a perspective view showing an elastic component according to a first modification. FIG.

In 8th an upper part shows an annularly formed elastic component 50A , In the lower part are four elastic components 51A (51Aa, 51Ab, 51Ac, 51Ad) in each case a part of the annular elastic component 50A forming form shown. The four elastic components 51A may be the same as the above elastic component 51 be arranged in the circumferential direction at a certain distance. For the elastic components 50A . 51A it is a film-like, a restoring force having resin component.

On the inside of the annular elastic component 50A a space S is provided, in which a part of the elastic component 50A can be included.

9 FIG. 15 is a perspective view showing an elastic component according to a second modification. FIG.

In 9 an upper part shows an annularly formed elastic component 50B , In the lower part are four elastic components 51B (51Ba, 51Bb, 51Bc, 51Bd) in a respective one part of the annular elastic component 50B forming form shown. The four elastic components 51B may be the same as the above elastic component 51 be arranged in the circumferential direction with a certain distance. at the elastic components 50B . 51B it is a resin component having a restoring force with a round cross-sectional shape.

On the inside of the ring-shaped elastic component 50B and the annularly arranged elastic component 51B a space S is provided in which a part of the elastic components 50B . 51B can be included. Further, between two adjacent elastic components 51B the four elastic components 51B a room S provided.

10 FIG. 15 is a perspective view showing an elastic component according to a third modification. FIG.

In 10 are in an upper part two, each as a semicircle slightly shorter elastic components 50C (50Ca, 50Cb). In the lower part are four elastic components 51C (51Ca, 51Cb, 51Cc, 51Cd) are shown in a respective part forming part of the annular elastic component. The four elastic components 51C can in the same way as the above elastic components 51 be arranged in the circumferential direction with a certain distance. For the elastic components 50C . 51C it is a resetting force having resin components with a cylindrical tube shape. Due to the cylindrical shape, the shift size of the plate 30 opposite the base 10 compared to the elastic components 50B . 51B be enlarged.

On the inside of the ring-shaped elastic components 50C . 51C a space S is provided in which a part of the elastic components 50C . 51C can be included. Further, between the two elastic components 50C and between two adjacent elastic components 51C the four elastic components 51C a room S provided.

11 FIG. 15 is a perspective view showing an elastic component according to a fourth modification. FIG.

In 11 are four elastic components 51D (51Da, 51Db, 51Dc, 51Dd). The four elastic components 51D can in the same way as the above elastic components 51 be arranged in the circumferential direction with a certain distance. For the elastic components 51D are each spherical, a restoring force having resin components.

On the inside of the four ring-shaped elastic components 51D a space S is provided, which is a part of the elastic components 51D can record. Further, between two adjacent elastic components 51D the four elastic components 51D a room S provided.

12 FIG. 15 is a perspective view showing an elastic component according to a fifth modification. FIG.

In 12 an upper part shows an annularly formed elastic component 50E , In the lower part are four elastic components 51E (51Ea, 51Eb, 51Ec, 51Ed) in each case a part of the annular elastic component 50E forming form shown. The four elastic components 51E can in the same way as the above elastic components 51 be arranged in the circumferential direction with a certain distance. For the elastic components 50E . 51E it is a film-like, a restoring force having resin components. On the surface of the elastic components 50E . 51E are recessed part and protruding part. Concretely speaking, on the surface of the elastic components 50E . 51E numerous small projections 55E intended. By this recessed part and projecting part, z. By providing such protrusions 55E, etc., the manner of deformation of the elastic components changes 50E . 51E against the case that there are no recessed part and no protruding part when the elastic components 50E . 51E be compressed. Therefore, the vibration generating device can 1 generated vibrations are changed.

On the inside of the ring-shaped elastic component 50E and the annularly arranged elastic component 51E a space S is provided, which is a part of the elastic components 50E . 51E can record. Further, between two adjacent elastic components 51E the four elastic components 51E provided a space S.

13 FIG. 15 is a perspective view showing an elastic component according to a sixth modification. FIG.

13 shows an annular formed elastic component 50F , At the elastic component 50F it is a resin component having a restoring force. The elastic component 50F has a ring-shaped sheet-like ring molding 55F and a plurality of parts protruding upward from the ring molding 55F 56F on. The respective outstanding parts 56F have a in the radial direction of the elastic component 50F extending rib shape.

On the inside of the ring-shaped elastic components 50F a space S is provided, which is part of the elastic component 50F can record. There is also between two protruding parts 56F the several outstanding parts 56F a room S provided.

The elastic component 50F is z. B. used in a state in which the upper part of the protruding parts 56F with the plate 30 in contact. When shifting the plate 30 downward, the respective protruding parts 56F are compressed in the top-bottom direction. Because the outstanding parts 56F away from each other in the circumferential direction and there is a room in which the protruding parts 56F are deformable in the circumferential direction, the respective protruding parts 56F Easier compressible in top-bottom direction. As a result, by using the integrally formed elastic component 50F in the same way as with the use of several elastic components, the displacement size of the plate 30 can be increased with respect to the strength of the magnetic attraction, and further, that of the coil 40 generated heat to be radiated.

Incidentally, z. B. according to the intended use of the vibration generating device 1 be suitably selected, whether an annularly formed elastic component is used, or a plurality of elastic components are arranged with a distance in the circumferential direction. As stated above, in the case where a plurality of elastic components are arranged at a pitch in the circumferential direction, the shift amount of the disk 30 can be increased with respect to the strength of the magnetic attraction, and further, that of the coil 40 generated heat to be radiated. On the other hand, in the use of the annularly formed elastic component on the inside and the outside of the elastic component, the gap between the plate 30 and the flange part 15 be eliminated. As a result, it can be prevented that it comes to defects, such. B. a hindrance to the displacement of the plate 30 by the penetration of a foreign body in the area on the inside of the elastic component.

[Explanation of the mounting structure of the vibration generating device 1 ]

14 FIG. 14 is a view showing the attachment structure of the vibration generating device. FIG 1 on the electronic device 1001 shows.

In 14 the structure of the details for the explanation is simplified. In 14 the state is shown in which in the coil 40 no electric current flows.

In the electronic device 1001 , a force sensor (example of a third elastic component) 1040 is between the contact component 1020 and the housing 1010 arranged. That is, the contact component 1020 is on the case 1010 via the force sensor 1040 fixed. The force sensor 1040 detects the force of the contact component 1020 is imposed when the contact component 1020 on the housing 1010 is depressed. The force sensor 1040 is formed by an elastic component having elasticity. Instead of the force sensor 1040, or together with the force sensor 1040 , Can also be an elastic component, such. As a leaf spring, a coil spring, a rubber or a plastic between the contact component 1020 and the housing 1010 to be ordered.

In the vibration generating device 1 is the top of the plate 30 in the bottom of the contact component 1020 opposite direction to the contact component 1020 fixed. The base 10 is in a state in which z. B. between the top of the flange 15 and the contact component 1020 a spacer 1091 is clamped by means of a screw 1090 extending from the underside of the flange portion 15 is inserted upward through the hole 11 and the spacer 1091, at the contact component 1020 fixed.

Between the case 1010 opposite bottom of the base 10 , the vibration generating device 1 and the vibration generating device 1 opposite top of the bottom surface of the housing 1010 , a gap is provided.

The plate 30 can in opposite to the base 10 Back and forth, ie in top-bottom direction, with the contact component 1020 come into contact and be spaced from this. In the present embodiment, the top of the plate stands 30 in the state where in the coil 40 no electric current flows to the bottom of the contact component 1020 in contact. In this way is at a contact of the plate 30 with the contact component 1020 the elastic component 51 slightly more compressed than in the natural state (state in which no the plate 30 to the base 10 reciprocating force is imposed). In other words, the elastic component 51 deformed, which with the contact component 1020 in contact plate 30 supports. That is, the vibration generating device 1 is in a state where the plate is 30 through the contact of the plate 30 with the contact component 1020 something is pressed down on the base 10 at the contact component 1020 fixed. In the state where the vibration generating device 1 at the contact component 1020 is fixed and the plate 30 with the contact component 1020 in contact causes the elastic component 51 that in opposite to the base 10 Back and forth the plate 30 to the contact component 1020 directed is shifted and the plate 30 on the contact component 1020 acts.

15 is a view showing the state of the vibration generating device 1 shows when an electric current passes through the coil 40 flows.

Flows into the coil 40 an electric current, the plate shifts 30 and approaches the base 10 at. At this point, the position of the base changes 10 Not. That is, at this time comes the plate 30 , as in 15 shown in one of the contact component 1020 removed (spaced) state.

Then it's going to be in the coil 40 flowing electric current is interrupted, and the magnetic attraction is lost. This will make the plate 30 by means of the restoring force of the elastic component 51 moved up and the plate 30 shifts to the contact component 1020 directed. The plate 30 shifts so much that it interacts with the contact component 1020 comes in contact, and stops in the contact state with the contact component 1020 , these being in the in 14 returned state.

In this way, the in 14 illustrated state and the in 15 illustrated state thereby repeatedly generates that the electric current repeatedly in the coil 40 flows in and is interrupted. Will the plate 30 repeatedly shifted back and forth, caused by the counteraction that the contact component 1020 at the plate 30 causes vibrations, with the vibrations on the contact component 1020 be transmitted. Because the contact component 1020 via the force sensor 1040 , which is an elastic component, with the housing 1010 is coupled, is a small shift of the contact component 1020 opposite the housing 1010 allowed. Because of that, too, on the case 1010 The vibrations transmitted can also be a user of the electronic device 1001 used, feel the vibrations.

Incidentally, the plate can 30 when in the coil 40 flowing electric current was interrupted and the plate 30 with the contact component 1020 in contact, with momentum on the contact component 1020 to meet. As an impact on the contact component 1020 can be generated, the user a relatively special feeling, such as a click-feeling mediated.

Incidentally, the attachment structure of the vibration generating device 1 not limited to this. Furthermore, the vibration generating device 1 apart from the electronic device 1001 used with various other electronic devices.

The vibration generating device 1 can z. B. also be mounted on the side of the housing instead of on the side of a contact component of the electronic device.

16 FIG. 15 is a perspective view showing a first modification of the fixing structure of the vibration generating apparatus. FIG 1 shows. 17 is a cross section showing the first modification of the attachment structure of the vibration generating device 1 shows.

As in 16 and 17 shown, it is the electronic device 1201 z. B. to a so-called smartphone, which is a contact component 1020 , a housing 1210, a force sensor 1040 and the vibration generating device 1 includes. In the electronic device 1201 is the vibration generating device 1 , different from the above electronic device 1001 , not on the side of the contact component 1020 but on the side of the case 1210 attached.

As in 17 is shown on the inside of the case 1010 a fixing member 1212 for fixing the vibration generating device 1 educated. The fastening part 1212 has a depression 1214 in the middle. The fastening part 1212 protrudes from the depression 1214, so that it forms the flange part 15 the vibration generating device 1 supports. In the vibration generating device 1 the fastening part 1212 is in a state in which the point at which the hole 11 of the flange part 15 is provided, is arranged resting on the fastening part 1212, by attaching a screw 1090 passed through the hole 11 from above.

In the present modification, the dimension from the top of the mounting part 1212 to the top of the recess 1214 is slightly larger than the dimension from the bottom of the flange part 15 the vibration generating device 1 to the bottom of the recessed part 14 , This is between the housing 1210 opposite surface of the vibration generating device 1 (here the bottom of the submerged part 14 ) and the vibrations generating device 1 opposite surface of the housing 1210 (Here, the top of the recessed portion 1214) provided a gap.

The plate 30 the vibration generating device 1 jams with the contact component 1020 the elastic component 1205 (second elastic component). That is, the elastic component 1205 is between the plate 30 and the contact component 1020 intended. Further, the elastic component 1205 is with the plate 30 and the contact component 1020 coupled or fixed directly or via another component such as an adhesive or the like. At the elastic component 1205 it is a component that has a dampening property. The elastic component 1205 is z. B. a resin component, such as. As a rubber or plastic. By providing the elastic component 1205 be the vibrations that the vibration generating device 1 generated by the elastic component 1205 something muted also on the contact component 1020 transfer. Further, when assembling the housing 1210 , the force sensor 1040 and the contact component 1020 the tolerance of the dimension between the housing 1210 and the contact component 1020 becomes relatively large, by the elastic component 1205 this tolerance balanced and the force due to the displacement of the plate 30 to the contact component 1020 be transmitted.

If necessary, the plate can 30 even without the elastic component 1205 with the contact component 1020 be coupled directly or via another component such as an adhesive or the like or fixed thereto.

18 Fig. 10 is a plan view showing a second modification of the attachment structure of the vibration generating apparatus. 19 is a cross section along the line CC in 18 ,

As in 18 and 19 shown, it is the electronic device 1601 z. B. to an electronic calculator in the form of a tablet, a contact component 1620 , a housing 1610 , an elastic component 1640 and the vibration generating device 1 includes. The contact component 1620 is a touchpad such as a touchscreen. The elastic component 1640 is z. Example, an elastic component such as a rubber or a plastic, and is between the contact component 1620 and the housing 1610 arranged. The elastic component 1640 is z. B. arranged so that they the outer periphery of the contact component 1620 surrounds.

As in 18 is shown in the electronic device 1601 the vibration generating device 1 on the outer periphery of the contact component 1620 fixed. That is, the vibration generating device 1 is with the contact component 1620 coupled in the way that the plate 30 with a part of the outer periphery of the contact component 1620 in contact. As in 19 is shown between the top of the base 10 the vibration generating device 1 and the inner surface of the housing 1610 provided a gap. In 19 The illustration of the internal structure of the vibration generating device 1 is omitted.

In this way, the vibration generating device 1 also be used in the case where the vibration generating device 1 on the outer circumference of the contact component 1620 is fixed, wherein the vibration generating device 1 generated vibrations on the contact component 1620 can be transmitted.

20 FIG. 15 is a perspective view showing a modification of the electronic device. FIG.

As in 20 shown, it is the electronic device 1401 z. B. to the steering wheel of a motor vehicle. The electronic device 1401 points in each case at three spoke parts 1407 connecting a hub 1405 and a handle 1403, contact components 1420 on. For the respective contact components 1420 are operating input parts, on which z. B. several control switches for the implementation of the selection and the setting relating to various functions of the motor vehicle are combined. The vibration generating device 1 is each on the back of the contact components 1420 attached. By using the vibration generating device 1 can vibrations in an operation of the operating switch of the respective contact components 1420 generated accordingly and a user feedback on the operation are taught.

As explained above, the vibration generating device 1 According to the first embodiment, a thin structure forming the base 10 , the sink 40 , the plate 30 and the elastic component 51 having. As a result, the vibration generating device having a relatively large vibration area can be used 1 be downsized. In the vibration generating device 1 form the basis 10 and the plate 30 a magnetic circuit. The vibration generating device 1 can effectively generate large vibrations. At the base 10 is the flange part 15 and the flange part 15 opposite is the plate 30 provided so that between the flange part 15 and the plate 30 which become a magnetic pole part which can not easily leak magnetic flux (decrease of the magnetic resistance), whereby even larger vibrations can be generated.

Between the plate 30 and the base 10 are several elastic components 51 arranged, the vertical dimension (thickness) is equal. As a result, the plate can 30 be moved while maintaining a horizontal position.

Second Embodiment

The basic structure of the vibration generating apparatus according to the second embodiment is the same as in the first embodiment, so that the explanation will not be repeated here. In the structure whose form or function is substantially identical to the structure explained in the first embodiment, the same reference numerals can be provided and an explanation thereof omitted. In the second embodiment, the shape of the arrangement of the elastic component, the structure of the base, etc., deviate from the first embodiment.

21 is a plan view of the vibration generating device 101 according to a second embodiment. 22 is a cross section along the line EE in 21 ,

In 21 FIG. 4 will explain the internal structure of the vibration generating device. FIG 101 the representation of the plate 30 omitted. That is, in the plan view of the actual vibration generating device 101 , are in 21 also the building components, from the plate 30 to be covered, represented by a solid line.

As in 21 and 22 shown has the vibration generating device 101 One Base 110 , a plate 30 , a coil 40 and elastic components 151 (151a, 151b, 151c, 151d, 151m).

In the second embodiment are at the base 110 a central protruding part 120 and an outer protruding part 125 attached. The central projecting part 120 is the same as the above part 20 of the first embodiment, in the recess 17 in the middle part of the recessed part 14 the base 110 arranged. In the outer protruding part 125 it is an annular component. The outer protruding part 125 is arranged so that it is the outside of the outer circumference of the coil 40 surrounds. In the bottom part 14a of the sunken part 14 the base 110 an annular recess 117b is formed, on which the outer projecting part 125 is fixed. The central projecting part 120 and the outer protruding part 125 become as well as the preceding part 20 formed from a magnetic body. For example, the central projecting part 120 and the outer projecting part 125 made of iron. As a result of in the coil 40 flowing electric current becomes the base 110 excited so that the upper part of the central projecting part 120 and the upper part of the outer protruding part 125 each become a magnetic pole part.

The central projecting part 120 and the outer protruding part 125 are formed so that their tops are each the same height as the top of the base 110 to have. The plate 30 is arranged so that the outer circumference of the plate 30 the top of the outer protruding part 125 opposite. Incidentally, at the base 110 the wide flange part 15 not provided, as in the first embodiment, the outer periphery of the recessed part 14 Surrounding is arranged so that only the section on both sides right and left of the recessed part 14 on which the hole 11 is provided is widened in a flange.

In the middle part of the top of the central protruding part 120 is a dent 120a formed in which an elastic component 151m (hereinafter especially as a central elastic component 151m is designated) is arranged. Further, on the outer protruding part 125 Indentations in four places 126 are formed, in each of which elastic components 151a, 151b, 151c, 151d (hereinafter in particular summarized as outer elastic components 151 be designated) at four indentations 126 to be ordered. In the second embodiment, the outer elastic components become 151 , in the same way as the elastic components 51 in the first embodiment, arranged in the circumferential direction with substantially equal distances next to each other. The depth of the indentation 120a and 126 is z. B. uniform, but this is not a limitation, so that the depth of the indentation 120a and the depth of the indentation 126 can also be different.

At the base 110 is a coil arrangement part between the recess 17 and the recess 117b 116 provided, which is slightly arched upwards. The central projecting part 120 is arranged in the recess 17. The outer protruding part 125 is arranged in the recess 17b. Above the coil assembly part 116 is the coil 40 arranged. As a result, a vibration generating device 1 are formed, which has a vibration area of a certain size, while the volume of the coil 40 , provided this is required is reduced. Further, in the magnetic circuit consisting of the base 110 and the plate can be prevented 30 is formed, that saturation of the magnetic flux at the portion of the bottom part 14a occurs. To the top of the coil 40 and the top of the central protruding part 120 To regulate to the same height, and the coil assembly part 116 be provided.

On top of the coil 40 is an insulating film (resin film) 145 arranged. Further, on the bottom of the coil 40 in the space to the coil assembly part 116 an insulating film (resin film) 146 arranged. In the insulating films (resin films) 145 . 146 is it z. B. Insulating resin components. This can be done between the coil 40 and the base 110 as well as between the coil 40 and the plate 30 a reliable insulation can be ensured.

In the second embodiment, the base 110 the central protruding part 120 and the outer protruding part 125 on, and the outer circumference of the plate 30 is arranged so that these the top of the outer projecting part 125 opposite. As a result, from the plate 30 , the central protruding part 120 of the base 110 , the outer protruding part 125 , and the section of the bottom part 14a a magnetic circuit is formed. As a result, the vibration generating device 101 be used in the same manner as in the above first embodiment. The vibration generating device 101 The second embodiment can be used in various electronic devices, as explained in the first embodiment.

As a relatively wide outer protruding part 125 can be used accordingly, the diameter of the plate 30 be increased, so that the performance of the vibration generating device 101 can be improved while the vibration area is increased.

Further, because at the central projecting part 120 and the outer protruding part 125 indentations 120a and 126 are formed, the gap between the plate 30 and the top of the base 110 and also the height in the top-bottom direction of the elastic component 151 be ensured for a long time. Will the plate 30 to the base 110 shifted and the elastic component 151 Compresses, decreases the degree to which the force of the resilient component that resists 151 increased, with the increase in the shift size of the plate 30 to, wherein this degree becomes smaller, the longer the elastic component 151 in up-down direction in the natural state. As a result, when in the coil 40 an electric current flows, the size of the between the plate 30 and the base 110 acting magnetic attraction and also increases the elastic component 151 be made easier to compress.

The central elastic component 151m is due to the displacement of the plate 30 down to the base 110 compressed, deforming in a diametrical direction becoming wider. As a result, the plate becomes 30 thus difficult to move in a horizontal direction, as the plate 30 through the central part of the plate 30 is stably supported when the plate 30 Repeats the shift in top-bottom direction. As a result, stable generation of vibrations can be effected.

23 Fig. 16 is a view showing a modification of the second embodiment.

As in 23 shown has the vibration generating device 201 One Base 210 , a plate 30 , a coil 40 and elastic components 151b, 151d. The vibration generating device 201 differs compared with the vibration generating device 1 according to the above second embodiment, mainly in the point that it does not have a central elastic component 151m and no coil arrangement part 116 having. Incidentally, in 23 a cross section through the elastic components 151b, 151d of the plurality of elastic components 151 shown.

The base 210 has the previous part 20 , the outer protruding part 125 and the spacer 228 on. The above part 20 is in the recess 17 of the bottom part 14a of the sunken part 14 arranged. The outer protruding part 125 is disposed in the annular recess 117b, which in the bottom part 14a is formed. The spacer 228 is between the preceding part 20 and the outer protruding part 125 on the bottom part 14a arranged. The spacer 228 has an outer diameter that is slightly smaller than the inner diameter of the outer protruding part 125 is, and an inner diameter slightly larger than the outer diameter of the protruding part 20 is, and has a ring shape. The spacer 228 is just like the previous part 20 and the outer protruding part 125 formed from a magnetic body. For example, the spacer is made 228 made of iron. By doing that, the spacer 228 is formed of a magnetic body, the magnetic performance of the magnetic circuit can be improved and the amplitude of the vibration generating device 1 generated vibrations are increased. The Kitchen sink 40 and the insulating films 145 . 146 are on the spacer 228 arranged. Incidentally, the spacer may be 228 also around a non-magnetic body, z. As a resin or the like, act. Used as a spacer 228 used insulating component having a better reliability of the insulation of the coil 40 be ensured.

Also in the vibration generating device 201 gets out of the plate 30 , the preceding part 20 the base 210 , the outer protruding part 125 , and the bottom part 14a a magnetic circuit is formed. As a result, the vibration generating device 201 be used in the same manner as in the second embodiment. Incidentally, the vibration generating device has 201 Although no central elastic component 151m by providing the further elastic components 151 can the vibration generating device 201 however, be used. It is also possible the central elastic component 151m provide so that the plate 30 even more stable in top-down direction can be moved.

Third Embodiment

24 is a plan view of the vibration generating device 401 according to a third embodiment. 25 is a cross section along the line GG in 24 ,

As in 24 and 25 shown has the vibration generating device 401 One Base 410 , a plate 430, a coil 40 and elastic components 151 (151a, 151b, 151c, 151d, 151m). The sink 40 , the above and below arranged insulating films 145 . 146 and the elastic components 151 are identical to those of the above second embodiment, so the explanation is omitted.

In the third embodiment, the base 410 a core 420 and a bottom plate 411 on.

The core 420 is a magnetic body. The core 420 exists z. B. iron. The core 420 has a total of z. B. column shape. The core 420 has a groove part 428 which sunk down from the top. As a result, from the point of view of the groove part 428 upwardly projecting a central projecting part 421 and an outer protruding part 425 intended. That is, the central protruding part 421 and the outer protruding part 425 are formed from a single component.

The sink 40 is together with the insulating films 145 . 146 arranged inside the groove part 428. The central projecting part 421 and the outer protruding part 425 meet in the vibration generating device 401 the same function as the central protruding part 120 and the outer protruding part 125 in the second embodiment. That is, as a result of in the coil 40 flowing electrical current becomes the core 420 excited so that the upper part of the central projecting part 421 and the upper part of the outer protruding part 425 each become magnetic poles.

At the bottom plate 411 it is broadly a square in plan view plate-shaped component. The section from the bottom plate 411 in which the core 420 from the bottom plate 411 is arranged, is to the recessed from the environment recess 414. The core 420 is arranged in the recess 414. Furthermore, in the front part of the bottom plate 411 a protruding part 419 is formed on which a terminal (not shown) is arranged. For example, on a part of the bottom or side surface of the groove part 428 of the core 420 a through hole, which leads to the outer surface of the core 420, or a recessed part (not shown) is provided, wherein a lead wire of the coil 40 is guided to the protruding part 419 through the through hole or the recessed part.

The bottom plate 411 can be made of a magnetic body, such. As iron, or may also be made of other types of component, such as. B. consist of a resin. Because of the bottom plate 411 is formed of a magnetic body, the magnetic performance of the magnetic circuit can be improved and the amplitude of the vibration generating device 401 generated vibrations are increased. Furthermore, it may be at the bottom plate 411 also z. B. may be a circuit board. At the bottom plate 411 It is not always necessary to provide the indentation 414 and the protruding part 419.

The elastic component 151 is on the top of the central protruding part 421 and the surface of the outer protruding part 425 arranged. On the elastic component 151 a disc-shaped plate 430 is arranged. This is done by the plate 430 and the core 420 , the central projecting part 421 and the outer protruding part 425 has formed a magnetic circuit. It gets a relatively large thickness of the core 420 in the top-bottom direction of the portion where the groove part 428 is provided. As a result, it is difficult for the magnetic circuit to saturate the magnetic flux.

In the corner parts of the bottom plate 411 are otherwise arranged rod-shaped support members 461, wherein the top-bottom direction becomes its length direction. Further, protruding parts 462 are provided on the upper surface of the plate 430, which protrude upward. To the support members 461 and the protruding parts 462, an annular rubber component 465 is placed. This will make the plate 430 opposite the base 410 holding holding structure 460 formed. The support structure 460 is z. B. each on parts right front, right rear, left front and left rear of the vibration generating device 401 intended. This prevents the plate 430 from falling off, with use for various uses and arrangements of the vibration generating device 401 is possible.

Also in the third embodiment is by the plate 430 and the core 420 , the central projecting part 421 and the outer protruding part 425 has formed a magnetic circuit. As a result, the vibration generating device 401 be used in the same manner as in the above first embodiment. The vibration generating device 401 in the third embodiment, as explained in the first embodiment, can be used in various electronic devices.

Fourth Embodiment

The basic structure of the vibration generating apparatus according to the fourth embodiment is the same as in the first embodiment, so that the explanation will not be repeated here. In the structure, its shape or function substantially with the structure explained in the first embodiment, the same reference numerals can be provided and an explanation thereof omitted.

26 is a cross section of the vibration generating device 601 according to the fourth embodiment.

As in 26 shown has the vibration generating device 601 One Base 10 , a plate 630 , a coil 40 and elastic components 51 (51a, 51b). The elastic components 51 be like in 5 and 6 , to several circumferentially next to each other on the flange 15 arranged. On the surface of the plate 630 that the base 10 is an outstanding part 635 intended. The outstanding part 635 is arranged to be a protruding part 620 of the base 10 opposite. Incidentally, the height of the protruding part 620 in the up-and-down direction becomes the proportion of the downwardly protruding part of the protruding part 635 lower.

Also in the fourth embodiment is by the outstanding part 635 and the outer circumference of the plate 630 , the protruding part 620, the bottom part 14a and the flange part 15 the base 10 a magnetic circuit is formed. As a result, the vibration generating device 601 be used in the same manner as in the above first embodiment. The outstanding part 635 the plate 630 also fulfills the role of a weight. That is, at the plate 630 is the outstanding part 635 provided as a weight, thereby a greater vibrational power can be generated, that the plate 630 is relatively heavy.

Incidentally, the weight may also be on a different surface than the underside of the plate 630 to be ordered. Further, a weight formed as a component separate from the plate 630 may also be attached to the plate 630 be attached.

The top of the in 26 shown coil 40 has the same height as the top of the flange 15 , In this way, the thickness of the coil 40 be increased, so that the magnetic attraction can be increased. Incidentally, there is no limitation, so that the surface of the coil 40 may also have the same height as the top of the protruding part 620.

Fifth Embodiment

The fundamental structure of the vibration generating apparatus according to the fifth embodiment is the same as in the first embodiment, so that the explanation will not be repeated here. In the structure, its shape or function substantially with the structure explained in the first embodiment, the same reference numerals can be provided and an explanation thereof omitted.

27 is a cross section of the vibration generating device 701 according to the fifth embodiment.

As in 27 shown has the vibration generating device 701 One Base 710 , a plate 730 , a coil 40 and elastic components 751 (751a, 751b).

The plate 730 has a structure in which the outer peripheral end part 732 is bent. That is, the outer peripheral end part 732 is from the top part 731 to the spool 40 bent over. The outer peripheral end part 732 is bent downwardly from the upper side part 731, which is the horizontal section.

In the present embodiment, the outer peripheral end part is located 732 the plate 730 further on the inside than the outer end part of the base 710 , Specifically, the outer peripheral end part is located 732 at the outer end part of the recessed part 14 the base 710 , ie further on the inside of the side wall part 14b. The plate 730 is on the side of the base 710 fixed so that the outer peripheral end part 732 in the sunken part 14 the base 710 penetrates. The outer peripheral end part 732 penetrates between the outer peripheral side surface of the spool 40 and the side wall part 14b the base 710 one. Between a lower end part of the outer peripheral end part 732 and the top of the bottom part 14a of the sunken part 14 the base 710 , are the elastic components 751 arranged. The elastic components 751 support in the same way as the elastic component 51 in the first embodiment, the plate 730 opposite the base 710 from.

In the fifth embodiment is through the plate 730 and the base 710 a magnetic circuit is formed. As a result, the vibration generating device 701 be used in the same manner as in the first embodiment. Since the outer peripheral end part 732 the plate 730 at the bottom part 14a and the side wall part 14b the base 710 is applied, leakage of the magnetic flux between the plate decreases 730 and the base 710 (Decrease of the magnetic resistance). As a result, the performance of the vibration generating device 701 be improved.

[Sixth Embodiment]

28 FIG. 15 is a perspective view showing the vibration generating apparatus 801 according to a sixth embodiment. FIG. 29 Fig. 12 is an explanatory view of the structure of the vibration generating apparatus 801 according to the sixth embodiment.

According to 28 and 29 has the vibration generating device 801 Overall, a rectangular shape. The vibration generating device 801 has a base 810 , a plate 830 , a coil 840 and elastic components 851 (851a, 851b).

The base 810 has on both sides left and right flange parts 815 in which holes 11 are formed, and in the central portion between the two flange parts 815 a recessed down sunken part 814 on. The sunken part 814 has a rectangular shape, wherein the length in the left-right direction is longer than the length in the front-back direction. In the sunken part 814 is the core 820 arranged. In the environment of the core 820 is a coil 840 arranged. The core 820 and the coil 840 are z. B. together with the shape of the recessed part 814 in a longitudinally oval shape in the left-right direction (including the shape of two semicircular arches connected by two straight lines).

The plate 830 , which is a top portion 831 as a horizontal portion, a right end portion, and a left end portion, has two of the top portion 831 to the spool 840 directed bent curved parts 832 on. The curvature parts 832 are further on the inside than the outer peripheral end part of the base 810 , More specifically, the curvature parts 832 further on the inside than the side wall part 814a of the recessed part 814 the base 810 , The plate 830 is on the side of the base 810 so fastened that the lower end part of the curvature parts 832 in the sunken part 814 the base 810 penetrates. The lower end part of the curvature parts 832 penetrates between the outer peripheral side surface of the spool 840 and the side wall part 814b the base 810 one. Between the lower end part of the curvature part 832 and the top of the recessed part 814 the base 810, are the elastic components 851 arranged. The elastic components 851 support in the same way as the elastic component 51 in the first embodiment, the plate 830 opposite the base 810 from.

In the sixth embodiment is by the plate 830 and the base 810 a magnetic circuit is formed. As a result, the vibration generating device 801 be used in the same manner as in the first embodiment. Because the curvature part 832 the plate 830 on the surface of the recessed part 814 the base 810 abuts and the side wall part 814b opposite, leakage of magnetic flux between the plate decreases 830 and the base 810 (Decrease of the magnetic resistance). As a result, the performance of the vibration generating device 801 be improved.

The components, such. B. the base 810 and the plate 830 , the vibration generating device 801 can z. B. be easily prepared by means of a linear bending machining.

30 FIG. 15 is a perspective view showing the vibration generating device 901 according to a modification of the sixth embodiment. 31 Fig. 12 is an explanatory view of the structure of the vibration generating apparatus 901 according to the modification of the sixth embodiment.

According to 30 and 31 has the vibration generating device 901 basically the same structure as the vibration generating device 801 according to the sixth Embodiment on. In the vibration generating device 901 will be in place of the plate 830 a rectangular plate 930 used. In addition, instead of the elastic components 851 on the top of the flange part 815 the base 810 elastic components 951 (951a, 951b). The right side part and the left side part of the plate 930 lie the flange part 815 the base 10 across from. The elastic components 951 are arranged so that they are between the right side part and the left side part of the plate 930 and the flange part 815 be trapped.

In the vibration generating device 901 become the flange parts 815 to a Magnetpolteil and from the plate 930 and the base 810 a magnetic circuit is formed. As a result, the vibration generating device 901 in the same way as in the vibration generating device 801 be used. Since the two side panels left and right of the plate 930 the flange parts 815 opposite, leakage of magnetic flux between the plate decreases 930 and the base 810 (Decrease of the magnetic resistance). As a result, the performance of the vibration generating device 901 be improved.

[Miscellaneous]

By suitably combining individual feature points of the above embodiments and their modifications, a vibration generating device can also be formed. For example, the outer shape of the in 18 illustrated vibration generating device 1 also in a disc shape, as in 4 represented, or in a cuboid shape, as in the later mentioned 28 shown to be brought. Furthermore, the in 18 illustrated vibration generating device 1 also suitably in one of the six vibration generating devices 101 . 201 . 401 . 601 . 701 . 801 or 901 the second to sixth embodiments are changed.

As further components may be known components such. Adhesive, the aforementioned elastic components and resin components or the like.

The vibration generating device is not limited to the above-exemplified flat shape or small shape. With a fundamentally identical construction, a construction of a large-scale vibration generating device is possible.

Further, the vibration generating device other than the above type of electronic device may be used in various other types of electronic devices. For example, the vibration generating device in various electronic devices, such. As a personal computer or its peripherals, a TV, a refrigerator, a washing machine or other electronic household appliances and electronic devices such. As remote controls for the operation of these, electronic devices that are used for devices for transport, or electronic devices that z. B. used for buildings, are applied.

In all of the above embodiments, it should be noted that these are examples of, but not limited to, examples. The scope of the present invention is illustrated not in the foregoing discussion but in the claims, which is intended to include all modifications in the same sense and within the scope of the claims.

LIST OF REFERENCE NUMBERS

1, 101, 201, 401, 601, 701, 801, 901

Vibration generating device

10, 110, 210, 410, 710, 810

Base

14, 814

sunk part

14a

the bottom part

14b, 814b

Sidewall portion

15.815

flange

20, 820

protruding part

30, 630, 730, 830, 930

plate

40, 840

Kitchen sink

51, 50A, 51A, 50B, 51B, 50C, 51C, 51D,

elastic component

50E, 51E, 50F, 151, 751, 851, 951

55E

head Start

56F

outstanding part

116

Coil placement part

120, 421

central protruding part

120a

indentation

125.425

outer protruding part

126

indentation

145, 146

insulating film (resin film)

151m

central elastic component

228

spacer

411

baseplate

420

core

635

outstanding part

732

outer end part

832

curvature part

1001, 1201, 1401, 1601

electronic device

1010, 1210, 1407, 1610

casing

1020, 1420, 1620

contact component

1040

force sensor

1205

elastic component

1640

elastic component

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2015070729 A [0003]

Claims (8)

An electronic device (1001; 1201; 1401; 1601) comprising a housing (1010; 1210; 1407; 1610), a contact component (1020; 1420; 1620) attached to the housing (1010; 1210; 1407; 1610) and a vibration generating device (1; 101; 201; 401; 601; 701; 801; 901), wherein the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) is fixed to either the contact component (1020; 1420; 1620) or to the housing (1010; 1210; 1407; 1610), and between the surface of the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) opposite to the housing (1010; 1210; 1407; 1610) and the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) opposite surface of the housing (1010; 1210; 1407; 1610) a gap is provided. Electronic device (1001, 1201, 1401, 1601) Claim 1 wherein the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) is coupled to or fixed to the contact component (1020; 1420; 1620) directly or via another component, wherein the vibration generating Apparatus (1; 101; 201; 401; 601; 701; 801; 901) having a base (10; 110; 210; 410; 710; 810) and a base (10; 110; 210; 410; 710; 810) reciprocating slidable plate (30; 630; 730; 830; 930), and the plate (30; 630; 730; 830; 930) being formed in relation to the base (10; 110; 210; 410; 710; 810) can be in contact with or spaced from the contact component (1020; 1420; 1620). Electronic device (1001, 1201, 1401, 1601) Claim 2 wherein the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) comprises a first resilient component (51) which supports the plate (30; 630; 730; 830; 930) opposite the base (30; 10; 110; 210; 410; 710; 810), the first elastic component (51) contacting the plate (30; 630; 730; 830; 930) in contact with the contact component (1020; 1420; 1620). supports, is deformed. Electronic device (1001, 1201, 1401, 1601) Claim 2 wherein the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) comprises a first resilient component (51) that supports the plate (30; 630; 730; 830; 930) opposite the base (30; 10; 110; 210; 410; 710; 810), the first elastic component (51) contacting the plate (30; 630; 730; 830; 930) in contact with the contact component (1020; 1420; 1620). in relation to the base (10; 110; 210; 410; 710; 810), the plate (30; 630; 730; 830; 930) translates to the contact component (1020; 1420; 1620) , Electronic device (1201) according to one of Claims 1 to 4 wherein a second elastic component (1205) is provided between the plate (30) and the contact component (1020). Electronic device (1601) according to one of Claims 1 to 4 wherein the contact component (1620) is coupled to the housing (1610) via a third resilient component (1640). Electronic device (1001, 1201, 1401, 1601) according to one of the Claims 1 to 6 wherein a weight is provided on the plate (30; 630; 730; 830; 930). Electronic device (1001, 1201, 1401, 1601) according to one of the Claims 1 to 7 wherein the vibration generating device (1; 101; 201; 401; 601; 701; 801; 901) is coupled to the outer periphery of the contact component (1020; 1420; 1620).

Images